Battery pack for use with a power tool and a non-motorized sensing tool

ABSTRACT

A system includes a power tool having a motor, a drive mechanism mechanically coupled to the motor, and an output element mechanically coupled to the drive mechanism. The motor is operable to drive the drive mechanism and the output element. The system also includes a non-motorized sensing tool having a printed circuit board and a sensing element electrically coupled to the printed circuit board. The sensing element is operable to detect an external characteristic and output a signal to the circuit board. The circuit board is operable to condition the signal into a human-comprehensible form. The system further includes a rechargeable battery pack removably and independently coupled to the power tool and the non-motorized sensing tool to power the motor to drive the drive mechanism and the output element when connected to the power tool and the circuit board and the sensing element when connected to the non-motorized sensing tool.

RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.13/596,379, filed Aug. 28, 2012, now U.S. Pat. No. 8,851,200, which is acontinuation of U.S. patent application Ser. No. 12/399,835, filed Mar.6, 2009, now U.S. Pat. No. 8,251,157, the entire contents of both ofwhich are hereby incorporated by reference. U.S. patent application Ser.No. 12/399,835 claims the benefit of U.S. Provisional Patent ApplicationNo. 61/034,801, filed Mar. 7, 2008 and U.S. Provisional PatentApplication No. 61/043,455, filed Apr. 9, 2008, the entire contents ofboth of which are also hereby incorporated by reference.

BACKGROUND

The present invention relates to battery packs and, more particularly,to battery packs for use with both power tools and non-motorized sensingtools.

Battery packs are often usable with a variety of different cordlesspower tools. For example, a single battery back may be independentlyconnected to a screwdriver, a drill, and a reciprocating saw (as well asother types of power tools) to provide power to the tools. Such powertools typically include relatively heavy motors and drive mechanismssuch that the additional weight of a battery pack is negligible.

Unlike cordless power tools, non-motorized sensing tools (e.g., visualinspection devices, wall scanners, thermometers, digital multimeters,clamp meters, etc.) are generally lightweight tools. These toolstypically include printed circuit boards having processors (rather thanmotors) and are powered by standard alkaline-based AA, AAA, or 9Vbatteries. Additionally, as a result of their size and weight,nickel-cadmium (NiCd) and nickel-metal hydride (NiMH) power tool batterypacks cannot reasonably be used with these devices. As such, if a useris using both types of tools for a particular job or project, it isinconvenient for the user to keep both a power tool battery pack andalkaline-based batteries on hand, and if the battery pack and thealkaline-based batteries are rechargeable, it is also inconvenient tokeep multiple types and sizes of chargers on hand for the differentbatteries.

SUMMARY

In one embodiment, the invention provides a system including a powertool having a motor, a drive mechanism mechanically coupled to themotor, and an output element mechanically coupled to the drivemechanism. The motor is operable to drive the drive mechanism and theoutput element. The output element produces an output force when drivenby the drive mechanism. The system also includes a non-motorized sensingtool having a printed circuit board and a sensing element electricallycoupled to the printed circuit board. The sensing element is operable todetect an external characteristic and output a signal indicative of thedetected characteristic to the printed circuit board. The printedcircuit board is operable to condition the signal into ahuman-comprehensible form. The system further includes a rechargeablebattery pack removably and independently coupled to the power tool andthe non-motorized sensing tool. The battery pack is operable to powerthe motor to drive the drive mechanism and the output element whenconnected to the power tool, and is operable to power the printedcircuit board and the sensing element when connected to thenon-motorized sensing tool.

In another embodiment, the invention provides a system including a firstnon-motorized sensing tool having a first printed circuit board, a firstsensing element electrically coupled to the first printed circuit board,and a display electrically coupled to the first printed circuit board.The first sensing element is operable to transmit image data of a remoteobject to the first printed circuit board. The first printed circuitboard is operable to condition the image data. The display is operableto display an image of the remote object based on the conditioned imagedata. The system also includes a second non-motorized sensing toolhaving a second printed circuit board and a second sensing elementelectrically coupled to the second printed circuit board. The secondsensing element is operable to detect a measurable characteristic of anobject and output a signal indicative of the measurable characteristicto the second printed circuit board. The second printed circuit board isoperable to condition the signal into a human-comprehensible form. Thesystem further includes a rechargeable battery pack having at least onelithium-ion battery cell. The rechargeable battery pack is removably andindependently coupled to the first non-motorized sensing tool and thesecond non-motorized sensing tool. The battery pack is operable to powerthe first printed circuit board, the first sensing element, and thedisplay when connected to the first non-motorized sensing tool, and isoperable to power the second printed circuit board and the secondsensing element when connected to the second non-motorized sensing tool.

In still another embodiment, the invention provides a system including apower tool having a first housing defining a first opening, a motorpositioned substantially within the first housing, and a drive mechanismpositioned substantially within the first housing and mechanicallycoupled to the motor. The motor is operable to drive the drivemechanism. The power tool also includes a first battery terminalsupported by the first housing and positioned within the first opening.The system also includes a non-motorized sensing tool having a secondhousing defining a second opening, a printed circuit board positionedsubstantially within the second housing, and a sensing elementpositioned substantially within the second housing and electricallycoupled to the printed circuit board. The sensing element is operable todetect an external characteristic and output a signal indicative of thedetected characteristic to the printed circuit board. The printedcircuit board is operable to condition the signal into ahuman-comprehensible form. The non-motorized sensing tool also includesa second battery terminal supported by the second housing and positionedwithin the second opening. The system further includes a rechargeablebattery pack removably and independently coupled to the power tool andthe non-motorized sensing tool. A portion of the battery pack isinsertable into the first opening of the power tool to engage the firstbattery terminal and substantially enclose the first opening. Theportion of the battery pack is insertable into the second opening of thenon-motorized sensing tool to engage the second battery terminal andsubstantially enclose the second opening. The first battery terminal andthe second battery terminal are generally exposed when the portion ofthe battery pack is removed from the first opening and the secondopening, respectively.

Other aspects of the invention will become apparent by consideration ofthe detailed description and accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a battery pack embodying the invention.

FIG. 2A is an exploded perspective view of the battery pack shown inFIG. 1.

FIG. 2B is a top view of the battery pack shown in FIG. 1.

FIG. 3 is a perspective view of a drill for use with the battery packshown in FIG. 1.

FIG. 4 is a perspective view of a visual inspection device for use withthe battery pack shown in FIG. 1.

FIG. 5 is an exploded perspective view of the visual inspection deviceshown in FIG. 4.

FIG. 6 is a perspective view of a wall scanner for use with the batterypack shown in FIG. 1.

FIG. 7 is an exploded perspective view of the wall scanner shown in FIG.6.

FIG. 8 is a block diagram depicting the wall scanner shown in FIG. 6.

FIG. 9 is a perspective view of a thermometer for use with the batterypack shown in FIG. 1.

FIG. 10 is an exploded perspective view of the thermometer shown in FIG.9.

FIG. 11 is a perspective view of a clamp meter for use with the batterypack shown in FIG. 1.

FIG. 12 is a perspective view of a secondary battery lock for use withthe clamp meter shown in FIG. 11.

FIG. 13 illustrates a battery pack for use with a variety of tools.

Before any embodiments of the invention are explained in detail, it isto be understood that the invention is not limited in its application tothe details of construction and the arrangement of components set forthin the following description or illustrated in the following drawings.The invention is capable of other embodiments and of being practiced orof being carried out in various ways. Also, it is to be understood thatthe phraseology and terminology used herein are for the purpose ofdescription and should not be regarded as limiting.

DETAILED DESCRIPTION

FIGS. 1, 2A and 2B illustrate a battery pack 20 for use with a varietyof devices. In the illustrated embodiment, the battery pack 20 is alithium-based, rechargeable battery pack for use with both power toolsand non-motorized sensing tools. The battery pack 20 is removably andinterchangeably connected to the tools to provide power during operationand to facilitate recharging of the battery pack 20 when not in use. Insome embodiments, the battery pack 20 may be used with other types ofcordless, battery-powered tools or devices not specifically discussedbelow.

The illustrated battery pack 20 includes a casing 24, an outer housing28 coupled to the casing 24, and a plurality of battery cells 32 (FIG.2A) positioned within the casing 24. The casing 24 is shaped and sizedto fit within an opening and cavity in a power tool or non-motorizedsensing tool to connect the battery pack 20 to the tool. The casing 24includes an end cap 36 to substantially enclose the battery cells 32within the casing 24. The illustrated end cap 36 includes two powerterminals 40 configured to mate with corresponding power terminalsextending from a tool. In other embodiments, the end cap 36 may includeterminals that extend from the battery pack 20 and are configured to bereceived in receptacles supported by a tool. The end cap 36 alsoincludes sense or communication terminals 42 (shown in FIG. 2B) that areconfigured to mate with corresponding terminals from a tool. Theterminals 42 couple to a battery circuit (not shown). The batterycircuit can be configured to monitor various aspects of the battery pack20, such as pack temperature, pack and/or cell state of charge, etc. andcan also be configured to send and/or receive information and/orcommands to and/or from a tool. In one embodiment, the battery circuitoperates as illustrated and described in U.S. Pat. No. 7,157,882entitled “METHOD AND SYSTEM FOR BATTERY PROTECTION EMPLOYING ASELECTIVELY-ACTUATED SWITCH,” issued Jan. 2, 2007, the entire contentsof which are hereby incorporated by reference. In another embodiment,the battery circuit operates as illustrated and described in U.S. PatentPublication No. 2006/0091858 entitled “METHOD AND SYSTEM FOR BATTERYPROTECTION,” filed May 24, 2005, the entire contents of which are alsohereby incorporated by reference.

The casing 24 and the receptacles 40 substantially enclose and cover theterminals on the tool when the pack 20 is positioned within the opening.That is, the battery pack 20 functions as a cover for the opening andterminals of the tool. Once the battery pack 20 is disconnected from thetool and the casing 24 is removed from the opening, the batteryterminals on the tool are generally exposed to the surroundingenvironment.

The outer housing 28 is coupled to an end of the casing 24 substantiallyopposite the end cap 36 and surrounds a portion of the casing 24. In theillustrated construction, when the casing 24 is inserted into orpositioned within the corresponding opening in the tool, the outerhousing 28 generally aligns with an outer surface of the tool. In thisconstruction, the outer housing 28 is designed to substantially followthe contours of the tool to match the general shape of the tool. In someembodiments, such as the embodiments discussed below, the casing 24 isinserted into a grip of a power tool or a non-motorized sensing tool. Insuch embodiments, the outer housing 28 generally increases (e.g.,extends) the length of the grip of the tool.

In the illustrated embodiment, two actuators 44 (only one of which isshown) and two tabs 48 are formed in the outer housing 28 of the batterypack 20. The actuators 44 and the tabs 48 define a coupling mechanism toreleasably secure the battery pack 20 to a power tool or non-motorizedsensing tool. Each tab 48 engages a corresponding recess formed in atool to secure the battery pack 20 in place. The tabs 48 are normallybiased away from the casing 24 (i.e., away from each other) due to theresiliency of the material forming the outer housing 28. Actuating(e.g., depressing) the actuators 44 moves the tabs 48 toward the casing24 (i.e., toward each other) and out of engagement with the recessessuch that the battery pack 20 may be pulled out of the opening and awayfrom the tool. Such an arrangement allows a user to quickly remove thebattery pack 20 from the tool for recharging or replacement without theuse of tools. In other embodiments, the battery pack 20 may includeother suitable coupling mechanisms to releasably secure the battery pack20 to a tool, as discussed below.

As shown in FIG. 2A, the battery pack 20 includes three battery cells 32positioned within the casing 24 and electrically coupled to theterminals 40. The battery cells 32 provide operational power (e.g., DCpower) to a power tool or non-motorized sensing tool. In the illustratedembodiment, the battery cells 32 are arranged in series, and eachbattery cell 32 has a nominal voltage of approximately four-volts(4.0V), such that the battery pack 20 has a nominal voltage ofapproximately twelve-volts (12V). The cells 32 also have a capacityrating of approximately 1.4 Ah. In other embodiments, the battery pack20 may include more or fewer battery cells 32, and the cells 32 can bearranged in series, parallel, or a serial and parallel combination. Forexample, the pack 20 can include a total of six battery cells 32 in aparallel arrangement of two sets of three series-connected cells 32. Theseries-parallel combination of battery cells creates a battery packhaving a nominal voltage of approximately 12V and a capacity rating ofapproximately 2.8 Ah. In other embodiments, the battery cells 32 mayhave different nominal voltages, such as, for example, 3.6V, 3.8V, 4.2V,etc., and/or may have different capacity ratings, such as, for example,1.2 Ah, 1.3 Ah, 2.0 Ah, 2.4 Ah, 2.6 Ah, 3.0 Ah, etc. In otherembodiments, the battery pack 20 can have a different nominal voltage,such as, for example, 10.8V, 14.4V, etc. In the illustrated embodiment,the battery cells 32 are lithium-ion battery cells having a chemistryof, for example, lithium-cobalt (Li—Co), lithium-manganese (Li—Mn), orLi—Mn spinel. In other embodiments, the battery cells 32 may have othersuitable lithium or lithium-based chemistries.

FIG. 3 illustrates one example of a motorized tool, such as power tool52 for use with the battery pack 20. In the illustrated embodiment, thepower tool 52 is a screwdriver or drill operable to drive a toolelement. The tool element can be, for example, a power tool accessorysuch as a drill bit 56 (e.g., a twist bit, a spade bit, an auger bit, amasonry bit, an installer bit, etc.). In other embodiments, the drill 52may drive other accessories, such as screwdriver bits, drill or bitadaptors, or the like. In still other embodiments, the power tool 52 maybe a different type of power tool such as, for example, a reciprocatingsaw, a circular saw, a pipe cutter, an impact driver, or the like, whichcan be used for power tool applications such as drilling, fastening,cutting, and material removal. In additional embodiments, the tool canbe a different type of motorized tool which drives an output elementsuch as a tape roll for a label maker or an ink cartridge for a printer.

The illustrated drill 52 includes a housing 60, a motor 64 positionedsubstantially within the housing 60, a drive mechanism 68 mechanicallycoupled to the motor 64, and a chuck 72 mechanically coupled to thedrive mechanism 68. The housing 60 includes a grip 76 extendinggenerally perpendicular relative to the motor 64 and the drive mechanism68 to support the battery pack 20. An opening in communication with acavity is formed in an end 80 of the grip 76 to receive the casing 24(FIGS. 1 and 2A) of the battery pack 20. As discussed above, the tabs 48(FIGS. 1 and 2A) of the battery pack 20 engage corresponding recessesformed on an inner surface of the cavity to releasably secure thebattery pack 20 to the drill 52. In some embodiments, the drill 52includes one or more LEDs for providing an indication to the user of thestatus of the drill 52, the battery pack 20, or both.

The motor 64 is coupled to the drive mechanism 68 to drive the drivemechanism 68 and rotate the chuck 72. In some embodiments, the motor 64,the drive mechanism 68, and the chuck 72 may output, for example,approximately 150 in-lbs of force. The chuck 72 receives and clamps thedrill bit 56 (or other accessory) for rotation with the chuck 72. As thedrill bit 56 rotates, the bit 56 outputs a force to cut a hole in a workpiece. In other embodiments, other output elements, such as ascrewdriver bit, may be coupled to the chuck 72 to, for example, rotateand drive a screw into a work piece.

As shown in FIG. 3, the drill 52 also includes a trigger 84 supported bythe housing 60 adjacent to the grip 76. The trigger 84 is electricallycoupled between the battery pack 20 and the motor 64 to selectivelyprovide power to the motor 64. Actuating the trigger 84 thereby controlsoperation of the drill 52 by rotating the motor 64 and the chuck 72 in aforward and/or reverse direction.

The drill 52 may also include a tool circuit (not shown) coupled to oneor more sense terminals or communication terminals (not shown). The toolcircuit includes, among other things, at least one switch for controland protection of the tool and battery pack. For example, in oneembodiment, the tool circuit includes a semi-conductor switch, such as afield effect transistor (FET), within a speed control circuit.Additionally or alternatively, the tool circuit includes a FET separatefrom the speed control circuit. The tool circuit is operable to monitora plurality of conditions of the tool including, but not limited to, thetemperature of the motor and an amount of current drawn from the batterypack. In some embodiments, the tool circuit is operable to communicatewith a control or protection circuit located within the battery pack. Inan illustrative embodiment, the battery pack and the tool circuit eachinclude a processor or controller. The controllers are, for example,microprocessors, microcontrollers, or the like, and are configured tocommunicate with one another. For example, the battery pack controllercan provide information to the tool circuit controller related to abattery pack temperature or voltage level. The power tool circuit andthe battery pack also include low voltage monitors and state-of-chargemonitors. The monitors are used by the tool circuit or the battery packto determine whether the battery pack is experiencing a low voltagecondition which may prevent proper operation of the drill, or if thebattery pack is in a state-of-charge that makes the battery packsusceptible to being damaged. If such a low voltage condition orstate-of-charge exists, the drill is shut down or the battery pack isotherwise prevented from further discharging current to prevent thebattery pack from becoming further depleted.

FIGS. 4 and 5 illustrate one example of a non-motorized sensing tool 88for use with the battery pack 20. In the illustrated embodiment, thesensing tool 88 is a visual inspection device for viewing the interiorof a confined space such as, for example, a pipe, a wall, a floor, anengine, or the like. The inspection device 88 allows an operator (e.g.,a plumber, an electrician, a mechanic, etc.) to view locations that areotherwise inaccessible without first dismantling or removing surroundingstructures. One example of a visual inspection device is illustrated anddescribed in U.S. patent application Ser. No. 12/399,755 entitled“VISUAL INSPECTION DEVICE”, filed Mar. 6, 2009, the entire contents ofwhich is hereby incorporated by reference.

The illustrated visual inspection device 88 includes a housing 92, aflexible cable 96 coupled to and extending from the housing 92, a cameraassembly 100 coupled to the flexible cable 96, a circuit such as, forexample, a printed circuit board (PCB) 104 (FIG. 5) positionedsubstantially within the housing 92, and a display 108 supported by thehousing 92. The housing 92 includes a support portion 112 for supportingthe display 108 and a grip 116 extending from the support portion 112.An elastomeric overmold 118, or skin, is coupled to the housing 92 tofacilitate gripping of the support portion 112 and to help protect thedevice 88 if the device 88 is banged into a surface or dropped.

Similar to the drill 52 discussed above, the grip 116 of the inspectiondevice 88 defines an opening 120 in communication with a cavity 121 toreceive the casing 24 of the battery pack 20. As shown in FIG. 5, thetabs 48 of the battery pack 20 engage recesses 122 formed on an innersurface 124 of the grip 116 to connect the battery pack 20 to thehousing 92. Terminals 128 positioned within the grip 116 engage thereceptacles 40 to electrically couple the battery pack 20 to the cameraassembly 100, the PCB 104, and the display 108.

As shown in FIG. 4, the flexible cable 96 is coupled to a stem 132extending from the housing 92. The cable 96 supports a plurality ofwires to electrically couple the PCB 104 to the camera assembly 100. Theillustrated cable 96 is flexible to bend around corners and throughpipes, but is also sufficiently rigid to maintain its shape whendesired. In the illustrated embodiment, the cable 96 is composed ofcarbon steel and covered or coated with a polyvinyl chloride (PVC) skinto decrease friction between the cable 96 and the surroundingenvironment.

The camera assembly 100 is coupled to a distal end of the flexible cable96 substantially opposite the stem 132. The illustrated camera assembly100 includes a generally cylindrical camera housing 136, a camera unitor image sensor 140 positioned within the camera housing 136, a lightsource 144 (e.g., an LED) positioned within the camera housing 136adjacent to the image sensor 140, and a lens 148 coupled to the camerahousing 136 to enclose the image sensor 140 and the light source 144. Inthe illustrated embodiment, the image sensor 140 is a charge coupleddevice (CCD), but may alternatively be a complementary metal oxidesemiconductor (CMOS). The image sensor 140 is operable to capture animage and/or video of a remote object and transfer image data relatingto the remote object to the PCB 104.

As shown in FIG. 5, the PCB 104 is positioned within the support portion112 of the housing 92 generally behind the display 108. The PCB 104 ispopulated with a plurality of electrical and electronic components whichprovide operational control and protection to the inspection device. Insome embodiments, the PCB 104 includes a control component or controllersuch as a microprocessor, a microcontroller, or the like. In someembodiments, the controller includes, for example, a processing unit, amemory, and a bus. The bus connects various components of the controllerincluding the memory to the processing unit. The memory includes, inmany instances, read only memory (ROM) and random access memory (RAM).The controller also includes an input/output system that includesroutines for transferring information between components within thecontroller. Software included in the implementation of the inspectiondevice of FIGS. 4 and 5 is stored in the ROM or RAM of the controller.The software includes, for example, firmware applications and otherexecutable instructions. In other embodiments, the controller caninclude additional, fewer, or different components.

The PCB also includes, for example, a plurality of additional passiveand active components such as resistors, capacitors, inductors,integrated circuits, and amplifiers. These components are arranged andconnected to provide a plurality of electrical functions to the PCBincluding, among other things, filtering, signal conditioning, andvoltage regulation. For descriptive purposes, a PCB (e.g., PCB 104) andthe electrical components populated on the PCB are collectively referredto herein as “the PCB.” The PCB 104 receives image data from the imagesensor 140, processes or conditions the image data, and transmits theconditioned image data to the display 108. The display 108 receives theconditioned image data and displays an image or video of the remoteobject for viewing by a user. In the illustrated embodiment, the display108 is a digital liquid crystal display (DLCD), although other suitabledisplays may alternatively be employed.

In a manner similar to that described above with respect to the drill52, the inspection device is operable to communicate with a controllerwithin the battery pack 20, and is operable to shut off or otherwiseprevent the battery pack 20 from discharging current when the batterypack 20 is experiencing a low voltage condition, or when the batterypack 20 is in a state-of-charge that is detrimental to the operation ofthe inspection device or could damage the battery pack 20 if it isfurther depleted.

The illustrated visual inspection device 88 also includes a plurality ofactuators 152 extending from the grip 116 of the housing 92. Theactuators 152 are coupled to a PCB 156 to control operation of thedevice 88. For example, depressing one or more of the actuators 152 mayturn the device 88 on and off, zoom in or pan across an image displayedon the display 108, rotate an image displayed on the display 108, adjustthe brightness of the light source 144, and/or store an image or a videoin an internal or external memory device. In addition, depressing one ofthe actuators 152 enters a menu mode of the device 88 such that a usermay control other functions and settings of the device 88. For example,a user may adjust the time and date, erase or transfer saved images andvideos, and/or input text or audio data relating to particular imagesand videos when in the menu mode. By depressing the appropriate actuator152, a list of options relating to the various settings of the device 88is displayed on the display 108. The actuators 152 allow a user to cyclethrough the various options and menu screens to select one of theoptions. As such, the inspection device 88 is a menu-driven device. Insome embodiments, the inspection device 88 includes one or more LEDs forproviding an indication to the user of the status of the inspectiondevice 88, the battery pack 20, or both.

FIGS. 6-8 illustrate another example of a non-motorized sensing tool 160for use with the battery pack 20. In the illustrated embodiment, thesensing tool 160 is a wall scanner for detecting studs, metallicobjects, and live wires behind a wall or other surface.

The illustrated wall scanner 160 includes a housing 164, a plurality ofwheels 168 rotatably coupled to the housing 164, a stud sensor 172 and aD-coil sensor 176 positioned substantially within the housing 164, acircuit, such as a PCB 180, positioned substantially within the housing164, and a display 184 supported by the housing 164. The housing 164includes a grip 188 extending generally parallel to the display 184along a centerline of the wall scanner 160. In some embodiments, thewall scanner 160 includes one or more LEDs for providing an indicationto the user of the status of the wall scanner 160, the battery pack 20,or both.

The PCB 180 is populated with a plurality of electrical and electroniccomponents in a manner similar to the PCB described above with respectto the inspection device 88. Similar to the tools 52, 88 discussedabove, the grip 188 of the wall scanner 160 defines an opening 190 incommunication with a cavity 192 to receive the casing 24 of the batterypack 20. As shown in FIG. 7, the tabs 48 of the battery pack 20 engagerecesses 194 formed on an inner surface 196 of the grip 188 to connectthe battery pack 20 to the housing 164. Terminals 200 positioned withingrip 188 engage the receptacles 40 to electrically couple the batterypack 20 to the sensors 172, 176, the PCB 180, and the display 184.

As shown in FIGS. 6 and 7, the wheels 168 are rotatably coupled to thehousing 164 to facilitate movement of the wall scanner 160 along asurface. In the illustrated embodiment, the wheels 168 are idle wheels,but may alternatively be driven wheels that are powered by the batterypack 20.

Referring to FIG. 8, the stud sensor 172 is electrically coupled to thePCB 180 and is operable to detect the presence of a stud, such as a woodstud or metal joist, behind a surface (e.g., a wall, a floor, a ceiling,etc.) of a residential, commercial, or industrial structure. The studsensor 172 detects wooden studs or metal joists hidden behind surfacescomposed of, for example, plaster, non-metallic wall materials, woodenpanels, wall board, or the like. The illustrated stud sensor 172includes two sensors 204A, 204B, each having a coplanar primary plate208A, 208B with a single side coplanar plate 212A, 212B arranged betweenthe primary plates 208A, 208B. When the stud sensor 172 detects a stud,the sensor 172 outputs a signal to the PCB 180 indicating the leadingand trailing edges of the stud and, in some embodiments, the material ofthe stud.

The D-coil sensor 176 is also electrically coupled to the PCB 180 and isoperable to detect both ferrous (i.e., iron based) and non-ferrous(e.g., copper) metals within structures. The D-coil sensor 176 detects,for example, rebar, metal conduit, and copper piping behind surfacescomposed of wall board, tile, plaster, brick, or the like. The D-coilsensor 176 may also detect metal within walls composed of concrete,masonry, wood, brick, or the like. The illustrated D-coil sensor 176uses an inductively coupled sensor that includes overlapping D-shapedtransmitter and receiver coils 216A, 216B. When the D-coil sensor 176detects a metallic object, the sensor 176 outputs a signal to the PCB180 indicating the location of the object.

In some embodiments, the wall scanner 160 may also include an ACdetection circuit for detecting the presence of live wires carryingalternating currents hidden behind a surface. In such embodiments, thewall scanner 160 may include an LED or other indicator for notifying auser when AC carrying wires are detected. The LED may be located on anend of the housing 164 substantially opposite the battery pack 20, onthe display 184, or both. The AC detection circuit may be operable todetect the presence of AC currents regardless of the operational mode(e.g., stud sensing mode or metal sensing mode) of the wall scanner 160.

As shown in FIG. 7, the PCB 180 is positioned within the housing 164adjacent to the stud sensor 172 and the D-coil sensor 176. The PCB 180receives signals from the sensors 172, 176, processes or conditions thesignals, and transmits the conditioned signals to the display 184. Thedisplay 184 receives the conditioned signals and displays an image, avalue (e.g., a distance, coordinates, etc.), or an alert relating to thedetected object. In the illustrated embodiment, the display 184 is aLCD, such as a negative LCD, although other suitable displays mayalternatively be employed.

In a manner similar to that described above with respect to the drill52, the wall scanner 160 is operable to communicate with a controllerwithin the battery pack, and is operable to shut off or otherwiseprevent the battery pack from discharging current when the battery packis experiencing a low voltage condition, or when the battery pack is ina state-of-charge that is detrimental to the operation of the wallscanner or could damage the battery pack if it is further depleted.

As shown in FIG. 6, the wall scanner 160 also includes a plurality ofactuators 220 extending through the housing 164 adjacent to the grip 188and the display 184. The actuators 220 are electrically coupled to thePCB 180 to control operation of the PCB 180 and the sensors 172, 176.For example, depressing one of the actuators 220 can turn the wallscanner 160 on and off, alternate between using the stud sensor 172(i.e., the stud sensing mode) and the D-coil sensor 176 (i.e., the metalsensing mode), and/or enter a menu mode of the scanner 160. When in themenu mode, a list of options relating to various settings of the scanner160 is displayed on the display 184. The actuators 220 allow a user tocycle through the various options and menu screens to select one of theoptions. As such, the wall scanner 160 is a menu-driven device.

As a result of the wall scanner 160 receiving operational power from thebattery pack 20, the wall scanner 160 is capable of including a varietyof additional features or functions that increase its power demand. Forexample, the wall scanner 160 can include a high-intensity LEDflashlight, a backlighted control section or actuators, ahigh-resolution LCD, a color LCD, and/or an additional or remotedisplay. Conventionally powered wall scanners (e.g., wall scannerspowered by alkaline batteries) are either unable to provide the requiredvoltage and current to power these additional features, or theoperational runtime (i.e., the amount of time for which the batteriescan power the wall scanner before the batteries need to be replaced orrecharged) of the alkaline batteries is shortened. In contrast, thebattery pack 20 is capable of powering both the additional features ofthe wall scanner 160 and the sensing and display features describedabove, while maintaining an operational runtime that is comparable to orlonger than a conventional wall scanner that does not include additionalfeatures.

FIGS. 9-10 illustrate yet another example of a non-motorized sensingtool 224 for use with the battery pack 20. In the illustratedembodiment, the sensing tool 224 is an infrared (IR) thermometer capableof detecting a temperature of a distant object or surface. The IRthermometer 224 allows a user to measure the temperature while eitherspaced away from an object or directly contacting the object with thethermometer 224.

The illustrated thermometer 224 includes a housing 228, an infrared (IR)temperature sensor 232 positioned within the housing 228, a laser 236positioned within the housing 228 adjacent to the IR temperature sensor232, a thermocouple 240 positioned within the housing 228, a circuit,such as a PCB 244 (FIG. 10), positioned within the housing 228, and adisplay 248 (FIG. 10) supported by the housing 228. The housing 228includes a grip 252 extending generally parallel relative to the display248. The PCB 244 is populated with a plurality of electrical andelectronic components in a manner similar to the PCB described abovewith respect to the inspection device 88 and the wall scanner 160.Similar to the tools 52, 88, 160 discussed above, the grip 252 of thethermometer 224 defines an opening 254 in communication with a cavity256 to receive the casing 24 of the battery pack 20. As shown in FIG.10, the tabs 48 of the battery pack 20 engage recesses 258 formed on aninner surface 260 of the grip 252 to connect the battery pack 20 to thehousing 228. Terminals 264 positioned within the grip 252 engage thereceptacles 40 (FIGS. 1 and 2A) to electrically couple the battery pack20 to the temperature sensor 232, the laser 236, the thermocouple 240,the PCB 244, and the display 248.

As shown in FIGS. 9 and 10, the illustrated grip 252 also supports atrigger 268 to control operation of the IR temperature sensor 232, thelaser 236, and/or the thermocouple 240. In some embodiments, such as theillustrated embodiment, the trigger 268 includes a lock 272 for takingcontinuous temperature measurements with one of the sensors 232, 240. Insome embodiments, the IR thermometer 224 includes one or more LEDs forproviding an indication to the user of the status of the IR thermometer224, the battery pack 20, or both.

Referring to FIG. 10, the IR temperature sensor 232 includes a lens anda detector. The lens focuses infrared energy onto the detector, whichthen converts the energy into a signal that is transmitted to the PCB244. The IR temperature sensor 232 also has an associateddistance-to-spot ratio (D:S). The D:S ratio is a ratio of a distance toan object and a diameter of a temperature measurement area. For example,if the D:S is 20:1, the IR temperature sensor 232 averages thetemperature of an object twenty feet away over an area with a one-footdiameter. In some embodiments, the IR temperature sensor 232 includessettings for measuring the temperature of both reflective andnon-reflective surfaces.

The thermocouple 240 is electrically coupled to the PCB 244 to provide asignal indicative of a contact temperature measurement. In theillustrated embodiment, the thermocouple 240 is a K-type thermocouple,although other suitable thermocouples may alternatively be employed. Thethermocouple 240 may be used independently of the IR temperature sensor232 or in conjunction with the IR temperature sensor 232 to, forexample, provide both contact and non-contact temperature measurementsof an object.

In the illustrated embodiment, the thermometer 224 also includes ahumidity sensor 276 positioned within the housing 228 and electricallycoupled to the PCB 244. The humidity sensor 276 provides a signal to thePCB 244 that is indicative of the humidity in the environmentsurrounding the thermometer 224. As such, the humidity sensor 276 isused for calibrating the IR temperature sensor 232 and for adjustingmeasurements made using the IR temperature sensor 232.

The illustrated PCB 244 is positioned within the grip 252 of the housing228. The PCB 244 receives signals from the sensors 232, 240, 276,processes or conditions the signals, and transmits the conditionedsignals to the display 248. The display 248 receives the conditionedsignals and displays one or more values relating to the measuredtemperatures. In addition, the display 248 also displays a valuerelating to the measured humidity. In the illustrated embodiment, thedisplay 248 is a LCD, such as a negative LCD, although other suitabledisplays may alternatively be employed.

In a manner similar to that described above with respect to the drill52, the IR thermometer 224 is operable to communicate with a controllerwithin the battery pack 20, and is operable to shut off or otherwiseprevent the battery pack 20 from discharging current when the batterypack 20 is experiencing a low voltage condition, or when the batterypack 20 is in a state-of-charge that is detrimental to the operation ofthe IR thermometer or could damage the battery pack 20 if it is furtherdepleted.

As a result of the wall scanner receiving operational power from thebattery pack 20, the IR thermometer 224 is capable of including avariety of additional features or functions that increase its powerdemand. For example, the IR thermometer 224 can include a high-intensityLED flashlight, a backlighted control section or actuators, ahigh-resolution LCD, a color LCD, and/or an additional or remotedisplay. Conventionally powered thermometers (e.g., thermometers poweredby alkaline batteries) are either unable to provide the required voltageand current to power these additional features, or the operationalruntime (i.e., the amount of time for which the batteries can power thethermometer before the batteries need to be replaced or recharged) ofthe alkaline batteries is shortened. In contrast, the battery pack 20 iscapable of powering both the additional features of the IR thermometer224 and the sensing and display features described above, whilemaintaining an operational runtime that is comparable to or longer thana conventional thermometer that does not include additional features.

As shown in FIG. 10, the thermometer 224 also includes a plurality ofactuators 280 that extend through the housing 228 adjacent to the grip252 and the display 248. The actuators 280 are electrically coupled tothe PCB 244 to control operation of the PCB 244 and the sensors 232,240, 276. For example, depressing one of the actuators 280 can turn thethermometer 224 on and off, alternate between non-contact and contactmeasurement modes, and/or enter a menu mode of the thermometer 224. Whenin the menu mode, a list of options relating to various settings of thethermometer 224 is displayed on the display 248. The actuators 280 allowa user to cycle through the various options and menu screens to selectone of the options. As such, the thermometer 224 is a menu-drivendevice.

FIG. 11 illustrates still another example of a non-motorized sensingtool 284 for use with the battery pack 20. In the illustratedembodiment, the sensing tool 284 is a clamp meter for measuring variousproperties or characteristics of a circuit element (e.g., a wire, aresistor, a capacitor, etc.) or other conductive object. The clamp meter284 allows a user to measure, for example, the electrical currentflowing through the circuit element without disconnecting the elementfrom the corresponding circuit.

The illustrated clamp meter 284 includes a housing 288, a clamp 292coupled to an end portion of the housing 288, a circuit, such as a PCB296, positioned substantially within the housing 288, and a display 300supported by the housing 288. The housing 288 includes a grip 304extending generally perpendicular relative to the PCB 296 and thedisplay 300. In some embodiments, the clamp meter 284 includes one ormore LEDs for providing an indication to the user of the status of theclamp meter 284, the battery pack 20, or both. The PCB 296 is populatedwith a plurality of electrical and electronic components in a mannersimilar to the PCB described above with respect to the inspection device88, the wall scanner 160, and the IR thermometer 224. Similar to thetools 52, 88, 160, 224 discussed above, the grip 304 of the clamp meter284 defines an opening to receive the casing 24 (FIGS. 1 and 2A) of thebattery pack 20. The tabs 48 (FIGS. 1 and 2) of the battery pack 20engage recesses formed on an inner surface of the grip 304 to connectthe battery pack 20 to the housing 288. Terminals positioned within thegrip 304 engage the receptacles 40 (FIGS. 1 and 2A) of the battery pack20 to electrically couple the clamp 292, the PCB 296, and the display300 to the battery pack 20.

As shown in FIG. 11, the grip 304 also supports a trigger 308 foractuating (e.g., opening and closing) the clamp 292. The trigger 308 iscoupled to, for example, a geared mechanical actuator that opens theclamp 292 when the trigger 308 is depressed and closes the clamp 292when the trigger 308 is released. In other embodiments, the clamp 292may be opened and closed electronically when the trigger 308 isdepressed and released.

The illustrated clamp 292 extends outwardly from the end portion of thehousing 288 generally perpendicular to the grip 304. The clamp 292supports and encloses a magnetic core for measuring current flowingthrough an object (e.g., a wire). When the clamp 292 is opened, the wireis positioned within an opening 312 defined by the clamp 292 such thatthe magnetic core substantially surrounds the wire. Once the clamp 292closes, the magnetic core begins measuring current flowing through thewire and outputs a signal indicative of the measured current to the PCB296.

The PCB 296 receives the signal from the clamp 292, processes orconditions the signal, and outputs the conditioned signal to the display300. The display 300 receives the conditioned signal and displays avalue (e.g., a number) corresponding to the measured current. In theillustrated embodiment, the display 300 is an LCD, such as a negativeLCD, but may alternatively be another suitable type of display.

In a manner similar to that described above with respect to the drill52, the clamp meter 284 is operable to communicate with a controllerwithin the battery pack 20, and is operable to shut off or otherwiseprevent the battery pack 20 from discharging current when the batterypack 20 is experiencing a low voltage condition, or when the batterypack 20 is in a state-of-charge that is detrimental to the operation ofthe clamp meter or could damage the battery pack 20 if it is furtherdepleted.

In some embodiments, devices herein include a secondary or redundantlocking mechanism or lockable structure which prevents a user fromeasily removing the battery pack. Accordingly, in some embodiments, theclamp meter 284 includes a secondary battery lock 400, as shown in FIG.12. The secondary battery lock 400 works in conjunction with theactuators 44 and tabs 48 of the battery pack 20, and is operable toredundantly secure the battery pack to the clamp meter 284. In theillustrated embodiment, the secondary battery lock 400 includes a firstend 402 having ball joints 404 for pivotably coupling the secondarybattery lock 400 to the housing 288 of the clamp meter 284. Thesecondary battery lock 400 includes a second end 406 having a flange 408for mating with a rib, groove, spine, etc. of the battery pack 20. Thesecondary battery lock 400 is positioned within an aperture (not shown)of the housing 288 at a lower portion of the grip 304, and is configuredsuch that it is only releasable using a separate tool, such as aflat-headed screwdriver or a knife. In other words, the secondarybattery lock 400 must be consciously opened or brought out of engagementwith the battery pack 20 before the battery pack 20 can be removed.

As a result of the clamp meter 284 receiving operational power from thebattery pack 20, the clamp meter 284 is capable of including a varietyof additional features or functions that increase its power demand. Forexample, the clamp meter 284 can include a high-intensity LEDflashlight, a backlighted control section or actuators, ahigh-resolution LCD, a color LCD, and/or an additional or remotedisplay. Conventionally powered clamp meters (e.g., clamp meters poweredby alkaline batteries) are either unable to provide the required voltageand current to power these additional features, or the operationalruntime (i.e., the amount of time for which the batteries can power theclamp meter before the batteries need to be replaced or recharged) ofthe alkaline batteries is shortened. In contrast, the battery pack 20 iscapable of powering both the additional features of the clamp meter 284and the sensing and display features described above, while maintainingan operational runtime that is comparable to or longer than aconventional clamp meter that does not include additional features.

In the illustrated embodiment, the clamp meter 284 also includespositive and negative terminals 316, 320 positioned on a rear surface324 of the housing 288 substantially opposite the clamp 292. Theterminals 316, 320 are operable to receive electrical leads for probes,allowing a user to test other electrical characteristics or propertiesof a circuit. For example, the terminals 316, 320 may help measure ACand DC current, AC and DC voltages, resistance, and capacitance ofvarious circuit elements. The terminals 316, 320 output signalsindicative of the measured characteristics to the PCB 296 for displayingon the display 300.

As shown in FIG. 11, the clamp meter 284 further includes a dial 328supported on an upper surface 332 of the housing 288. The dial 328 iselectrically coupled to the PCB 296 to change the operating mode of theclamp meter 292. That is, actuating (e.g., rotating) the dial 328adjusts the clamp meter 292 to measure an output, for example, AC or DCcurrent, AC or DC voltage, capacitance, and/or resistance of an object.In addition, one position of the dial 328 is an off position tointerrupt power flowing from the battery pack 20 to the clamp meter 284.

In the illustrated embodiment, the clamp meter 284 also includes aplurality of functional buttons 336 to perform other functions with andadjust settings of the clamp meter 284. For example, one functionalbutton 336 may be actuated to zero the clamp meter 284, one functionalbutton 336 may be actuated to change the units of a displayed value, onefunctional button 336 may be actuated to temporarily hold or save adisplayed value, one functional button 336 may be actuated to displayminimum and maximum measured values, and one functional button 336 maybe actuated to display only a peak or inrush value.

Accordingly, the battery pack 20 is usable with both power tools (e.g.,the drill 52) and non-motorized sensing tools (e.g., the visualinspection device 88, the wall scanner 160, the thermometer 224, and theclamp meter 284). Typically, a battery pack that is used with a powertool is too heavy and bulky for use with non-motorized, software-driventools. However, lithium-ion battery packs enable the use of high-voltageremovable and rechargeable battery packs with these non-motorizedsensing tools. The illustrated battery pack 20 includes battery cells 32having a lithium-based chemistry such that the battery pack 20 is over65% lighter and 50% smaller than an equivalent nickel-cadmium (NiCd)battery pack. The lithium-ion battery pack 20 also provides a longeroperational run-time for each tool, and a longer life (e.g., number ofrecharge cycles) than the other non-lithium based battery packs.

Additionally, as described above, the battery pack 20 is also capable ofproviding operational power to a plurality of additional features orfunctions of the inspection device, the wall scanner, the IRthermometer, and the clamp meter. For example, the additional functionsor features can include a high-intensity LED flashlight, a backlightedcontrol section or actuators, a high-resolution LCD, a color LCD, and/oran additional or remote display.

In addition, the illustrated battery pack 20 is designed to partiallyfit within a grip of a tool such that the battery pack 20 does notgreatly increase the overall size of the tool. In particular, the outerhousing 28 of the battery pack 20 functions as both a grip for the tooland a cover for battery terminals of the tool when the battery pack 20is inserted into an opening or cavity formed in the tool.

Furthermore, providing a battery pack that is usable with a variety oftools (i.e., motorized power tools and non-motorized sensing tools)allows a user to only purchase and/or keep one or a few battery packs onhand. For example, a user can purchase a variety of tools, such as thoseshown in FIG. 13, in a single kit that includes one or more batterypacks 20 and a single charger. The user is not required to purchaseadditional battery chargers for charging different types of batteries,and the user is not required to purchase replacement batteries such asis required for devices which operate on alkaline batteries. In additionand because each tool can be operated by a single type of battery pack,the flexibility and usability of the system of tools is maximized. As anillustrative example, a user can use a first non-motorized sensingdevice, such as the IR thermometer 224, to detect the temperature of anelectrical utility box. The user can then access the utility box using amotorized power tool, such as the drill 52. After accessing theelectrical utility box, the user can detect the amount of currentflowing through a wire using a second non-motorized sensing device, suchas the clamp meter 284. In the described example, the IR thermometer,the drill, and the clamp meter can be operated using a single removableand rechargeable battery pack 20. The user can simply interchange thebattery pack from tool to tool as needed.

In another embodiment, the user can use a first non-motorized sensingdevice, such as the wall scanner 160, to detect the presence of anobject (e.g., a stud, electrical conduit, etc.) hidden behind a surface.The user can then remove a small portion of the surface using amotorized power tool, such as a reciprocating saw 424 (shown in FIG.13), to gain access to the area behind the surface. After accessing thearea behind the surface, the user can inspect the area using a secondnon-motorized sensing device, such as the inspection device 88.

In yet another embodiment, the user can use a first motorized powertool, such as the drill 52, to gain access to a secured electricalcontrol box (e.g., a circuit breaker box). The user can then testvarious circuits and wires for voltages, currents, continuity, etc.using a non-motorized sensing tool, such as the clamp meter 284. Aftertesting is complete, the user can label, for example, wires, circuitbreakers, or the control box using a second motorized tool, such as alabel maker.

Additionally or alternatively, if the battery pack of a power tool islow on power, the user can remove the battery pack from a non-motorizedtool that he/she is not using and connect the battery pack to the powertool, or vice versa. Using one type of battery pack for a variety oftools also only requires the user to keep one battery charger on handfor charging the battery packs.

FIG. 13 illustrates the compatibility of the battery pack 20 with avariety of tools. For example, the battery pack 20 is compatible withthe drill 52, the inspection device 88, the clamp meter 284, the IRthermometer 224, the wall scanner 160, a pipe cutter 420, an impactdriver 422, and a reciprocating saw 424.

Although the invention has been described in detail with reference topreferred embodiments, variations and modifications exist within thescope and spirit of one or more independent aspects of the invention asdescribed. Various features and advantages of the invention are setforth in the following claims.

What is claimed is:
 1. A system comprising: a power tool including ahousing, a motor, a drive mechanism mechanically coupled to the motor,and an output element mechanically coupled to the drive mechanism, thehousing defining an opening, the motor operable to drive the drivemechanism and the output element, the output element producing an outputforce when driven by the drive mechanism; a non-motorized sensing toolincluding a housing, a printed circuit board and a sensing elementelectrically coupled to the printed circuit board, the housing definingan opening that is similarly shaped and sized relative to the openingdefined in the housing of the power tool, the sensing element operableto detect a characteristic external to the sensing tool and output asignal indicative of the detected characteristic; and a rechargeablebattery pack configured to be removably and independently coupleable tothe power tool and the non-motorized sensing tool, the battery packoperable to provide power to the motor to drive the drive mechanism andthe output element when connected to the power tool, and operable toprovide power to the printed circuit board when connected to thenon-motorized sensing tool, at least a portion of the battery pack beingpositioned within the opening of the power tool to connect to the powertool and alternatively being positioned within the opening of thenon-motorized sensing tool to connect to the non-motorized sensing tool,wherein the rechargeable battery pack includes a housing, at least onelithium-based battery cell positioned within the housing, a terminal,and a latch mechanism, wherein, when the battery pack is coupled to thepower tool, the latch mechanism engages the housing of the power tool tosecure the battery pack to the power tool such that a portion of thebattery pack housing remains exposed, and wherein, when the battery packis coupled to the non-motorized sensing tool, the latch mechanismengages the housing of the non-motorized sensing tool to secure thebattery pack to the non-motorized sensing tool such that the portion ofthe battery pack housing remains exposed.
 2. The system of claim 1,wherein the non-motorized sensing tool is a menu-driven device having aplurality of settings, and wherein the non-motorized sensing toolincludes a selector to adjust at least one of the plurality of settings.3. The system of claim 1, wherein the non-motorized sensing toolincludes a visual inspection device and the sensing element includes animage sensor, and wherein the image sensor is operable to transmit imagedata of a remote object to the printed circuit board.
 4. The system ofclaim 1, wherein the non-motorized sensing tool includes a thermometerand the sensing element includes an infrared temperature sensor, andwherein the infrared temperature sensor is operable to sense atemperature of an object and transmit a signal indicative of the sensedtemperature to the printed circuit board.
 5. The system of claim 1,wherein the power tool is selected from the group consisting of a drill,a reciprocating saw, a circular saw, a pipe cutter, and an impactdriver.
 6. The system of claim 1, wherein the power tool communicativelyconnects to the battery pack via the sense terminal.
 7. The system ofclaim 6, wherein the power tool is configured to receive informationfrom the battery pack via the sense terminal.
 8. The system of claim 7,wherein the information includes a voltage indicative of astate-of-charge associated with the battery pack.
 9. The system of claim8, wherein the state-of-charge is a state-of-charge associated with theat least one lithium-based battery cell.
 10. The system of claim 1,wherein the sensing tool communicatively connects to the battery packvia the sense terminal.
 11. The system of claim 10, wherein the sensingtool is configured to receive information from the battery pack via thesense terminal.
 12. The system of claim 11, wherein the informationincludes a voltage indicative of a state-of-charge associated with thebattery pack.
 13. The system of claim 12, wherein the state-of-charge isa state-of-charge associated with the at least one lithium-based batterycell.
 14. A system comprising: a power tool including a first housingdefining a first opening, a motor positioned substantially within thefirst housing, a drive mechanism mechanically coupled to the motor, themotor operable to drive the drive mechanism, and a first batteryterminal positioned within the first opening; a non-motorized sensingtool including a second housing defining a second opening, the secondopening being similarly shaped and sized relative to the first opening,a printed circuit board positioned substantially within the secondhousing, a sensing element electrically coupled to the printed circuitboard, the sensing element operable to detect a characteristic externalto the sensing tool and output a signal indicative of the detectedcharacteristic, and a second battery terminal positioned within thesecond opening; and a rechargeable battery pack configured to beremovably and independently coupleable to the power tool and thenon-motorized sensing tool, a portion of the battery pack beinginsertable into the first opening of the power tool to engage the firstbattery terminal, the portion of the battery pack being insertable intothe second opening of the non-motorized sensing tool to engage thesecond battery terminal, the first battery terminal and the secondbattery terminal being generally exposed when the portion of the batterypack is removed from the first opening and the second opening,respectively, wherein the rechargeable battery pack includes a housing,at least one lithium-based battery cell positioned within the housing, aterminal, and a latch mechanism, wherein, when the battery pack iscoupled to the power tool, the latch mechanism engages the first housingto secure the battery pack to the power tool such that a portion of thebattery pack housing remains exposed, and wherein, when the battery packis coupled to the non-motorized sensing tool, the latch mechanismengages the second housing to secure the battery pack to thenon-motorized sensing tool such that the portion of the battery packhousing remains exposed.
 15. The system of claim 14, wherein thenon-motorized sensing tool includes a visual inspection device and thesensing element includes an image sensor.
 16. The system of claim 14,wherein the non-motorized sensing tool includes a thermometer and thesensing element includes an infrared temperature sensor, and wherein theinfrared temperature sensor is operable to sense a temperature of anobject and transmit a signal indicative of the sensed temperature to theprinted circuit board.
 17. The system of claim 14, wherein the powertool is selected from the group consisting of a drill, a reciprocatingsaw, a circular saw, a pipe cutter, and an impact driver.
 18. A systemcomprising: a power tool including a housing, a motor, a drive mechanismmechanically coupled to the motor, and an output element mechanicallycoupled to the drive mechanism, the housing defining an opening, themotor operable to drive the drive mechanism and the output element, theoutput element producing an output force when driven by the drivemechanism; a non-motorized sensing tool including a housing, a printedcircuit board and a sensing element electrically coupled to the printedcircuit board, the housing defining an opening that is similarly shapedand sized relative to the opening defined in the housing of the powertool, the sensing element operable to detect a characteristic externalto the sensing tool and output a signal indicative of the detectedcharacteristic; and a rechargeable battery pack configured to beremovably and independently coupleable to the power tool and thenon-motorized sensing tool, the battery pack operable to power the motorto drive the drive mechanism and the output element when connected tothe power tool, and operable to power the printed circuit board and thesensing element when connected to the non-motorized sensing tool, atleast a portion of the battery pack being positioned within the openingof the power tool to connect to the power tool and alternatively beingpositioned within the opening of the non-motorized sensing tool toconnect to the non-motorized sensing tool, wherein the power tool isselected from the group consisting of a drill, a reciprocating saw, acircular saw, a pipe cutter, and an impact driver.
 19. The system ofclaim 18, wherein the non-motorized sensing tool includes a visualinspection device and the sensing element includes an image sensor, andwherein the image sensor is operable to transmit image data of a remoteobject to the printed circuit board.
 20. The system of claim 18, whereinthe non-motorized sensing tool includes a thermometer and the sensingelement includes an infrared temperature sensor, and wherein theinfrared temperature sensor is operable to sense a temperature of anobject and transmit a signal indicative of the sensed temperature to theprinted circuit board.